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Cellular Differentiation00:57

Cellular Differentiation

5.0K
How does a complex organism such as a human develop from a single cell? It all starts from a single fertilized egg which gives rise to a vast array of cell types, such as nerve cells, muscle cells, and epithelial cells that characterize the adult? Throughout development and adulthood, cellular differentiation leads cells to assume their final morphology and physiology. Differentiation is the process by which unspecialized cells become specialized to carry out distinct functions.
A zygote is a...
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iPS Cell Differentiation01:22

iPS Cell Differentiation

3.0K
The ability of induced pluripotent stem cells or iPSCs to differentiate into most body cell types has stimulated repair and regenerative medicine research over the past few decades. iPSC-derived blood cells, hepatocytes, beta islet cells, cardiomyocytes, neurons, and other cell types can repair injuries or regenerate damaged tissue in diseases such as diabetes and neurodegenerative disorders.
3.0K
Maintenance of the ES Cell State01:14

Maintenance of the ES Cell State

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The cells of the blastocyst inner cell mass only remain pluripotent for a short time. This state of pluripotency and self-renewal can be maintained in embryonic stem (ES) cell culture by adding specific chemicals or growth factors to ensure the cells can continue dividing and later differentiate into different cell types. In some cases, the cells are grown on a feeder layer of differentiated cells, which provides the growth factors and extracellular matrix components necessary for stem cell...
2.7K
Somatic to iPS Cell Reprogramming01:29

Somatic to iPS Cell Reprogramming

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Reprogramming alters the gene expression in somatic cells, transforming them into induced pluripotent stem (iPS) cells over several generations. Scientists can reprogram cells by introducing genes for four transcription factors—Oct4, Sox2, Klf4, and c-Myc (OSKM) by viral or non-viral methods. These factors are also known as Yamanaka factors after Shinya Yamanaka, who first generated iPS cells using mouse skin cells. Yamanaka was awarded the Nobel Prize in Physiology or Medicine in 2012...
2.6K
Master Transcription Regulators02:23

Master Transcription Regulators

7.7K
Master transcription regulators are regulatory proteins that are predominantly responsible for regulating the expression of multiple genes. Often these genes work in concert to drive a  complex process. Activation of a master transcription regulator can lead to a cascade of transcriptional activation necessary for that outcome. These regulators can directly bind to the regulatory sequences of the various genes involved, or they can indirectly regulate transcription by binding to regulatory...
7.7K
Assembly of Complex Microtubule Structures01:32

Assembly of Complex Microtubule Structures

2.4K
Complex microtubule structures are present in resting cells and in dividing cells. In resting cells, they are responsible for maintaining the cellular architecture, tracks for intracellular transport, positioning of organelles, assembly of cilia and flagella. They mediate the bipolar spindle assembly for chromosomal segregation and positioning of the cell division plate in dividing cells. The formation of microtubule complex structures depends on the cell type, cell stage, and cell function.
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Related Experiment Video

Updated: Jan 11, 2026

Initiating Differentiation in Immortalized Multipotent Otic Progenitor Cells
12:17

Initiating Differentiation in Immortalized Multipotent Otic Progenitor Cells

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Functions of TIP60/NuA4 Complex Subunits in Cell Differentiation.

Fatemeh Hashemi1,2, Aida Nourozi3, Mojtaba Shaban Loushab1

  • 1Arnie Charbonneau Cancer Institute, Cumming School of Medicine, University of Calgary, Calgary, AB T2N 4N1, Canada.

Cells
|November 13, 2025
PubMed
Summary

The TIP60/NuA4 complex, a key epigenetic regulator, influences cell differentiation by altering chromatin structure. Its subunits and catalytic activity are crucial for lineage specification and developmental transitions.

Keywords:
ING3TIP60/NuA4 complexdifferentiationhistone acetyltransferasestem cells

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Differentiation of a Human Neural Stem Cell Line on Three Dimensional Cultures, Analysis of MicroRNA and Putative Target Genes
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Area of Science:

  • Epigenetics
  • Molecular Biology
  • Cellular Differentiation

Background:

  • The TIP60/NuA4 complex is a large histone acetyltransferase involved in epigenetic regulation.
  • It plays a role in transcription, cell cycle, and apoptosis.
  • Its recruitment to active transcription sites is mediated by H3K4me3 recognition via ING3.

Purpose of the Study:

  • To review how TIP60/NuA4 subunit alterations impact chromatin structure and transcriptional activity.
  • To examine the influence of these changes on cell differentiation.
  • To highlight the molecular mechanisms of TIP60/NuA4 in lineage specification.

Main Methods:

  • Review of existing literature on TIP60/NuA4 complex function.
  • Analysis of molecular mechanisms involving histone acetylation and variant exchange.
  • Integration of mechanistic insights with functional outcomes in differentiation.

Main Results:

  • Altered subunit levels or mutations in TIP60/NuA4 affect chromatin structure and gene expression.
  • Specific subunits like KAT5 and EP400 are critical for histone modifications (H2A, H4 acetylation, H2A.Z incorporation).
  • Interactions with transcription factors (MyoD, PPARγ, Myc) are essential for lineage specification.

Conclusions:

  • TIP60/NuA4 acts as a central epigenetic hub orchestrating cell differentiation.
  • The complex is vital for proper developmental transitions and lineage specification.
  • Understanding TIP60/NuA4 mechanisms provides insights into developmental processes.